Tag Archives: Intel Hyperthreading

PortSmash Vulnerability: What you need to know

Security researchers have released details of a new side channel attack known as “PortSmash” that can be used to steal information from processes running inside a computer systems CPU (defined)) when Intel Hyperthreading (HT)(defined here and here) is enabled. Their proof of concept allowed them to steal a private decryption from a thread running in the same core as their exploit. This thread belonged to an OpenSSL process.

How severe is this vulnerability?
It has been designated as CVE-2018-5407 and assigned a base score of 4.8 (medium severity) on the CVSS v3 scale (defined) with a high attack complexity and with only low privileges required. The attack cannot be exploited remotely. An attacker must have been able to compromise your system via another means most likely a phishing email (social engineering)(phishing: defined; social engineering: defined), accidentally clicking a malicious link or a drive by download (defined). The attacker will also still need to have their code running within the same core as the data/code they wish to obtain. Similar to Spectre; multi-tenant cloud environments are more at risk.

Red Hat’s security advisory states “In order to exploit this flaw, the attacker needs to run a malicious process on the same core of the processor as the victim process”. PortSmash is fundamentally different from Meltdown and Spectre vulnerabilities; it does not rely on speculative execution.

Collin Percival, a Computer Scientist summed up the attack as follows:

“I’ve been getting a few questions about the recent “PortSmash” vulnerability announcement. Short answer: This is not something you need to worry about. If your code is vulnerable to it, you were already vulnerable to other (easier) attacks.

He advises that users don’t need to worry about it and states: “the defence against microarchitectural side channel attacks from 2005: Make sure that the cryptographic key you’re using does not affect the sequence of instructions or memory accesses performed by your code”.

How does this vulnerability work?
When a thread (defined) is carrying out some work it has its own instructions (what to do) and data (the objects to work on) but it will share some of its hardware resources with another process operating on a collocated thread.

The attackers can obtain information about the decryption key by analysing how fast the (process) thread within the CPU is operating with particular assembly language (defined) instructions and uses that information to work backwards (reverse engineering) on what possible data was used as the input to achieve this data now being processed. In this case the data is a private decryption key (defined).

Explained another way: This attack uses instruction timing (how long it takes to process) based on port contention. Each core of a CPU has physical regions known as ports which carry out the necessary calculations. If two or more threads are processing at the same they may have to wait on each other to use those regions of the CPU.

PortSmash seeks to monopolise a port which is being shared with a thread with information the attack wishes to obtain. They can measure the time taken between instructions of the attackers thread and the legitimate thread (thus determining how long the legitimate thread spend processing). This will help to obtain the data being processed over a long period of time

PortSmash is a side channel attack meaning that the attacker doesn’t immediately find out the protected/secret value immediately; instead the attack seeks out information from the other thread running within the CPU for information on the secret value being processed.

The proof of concept code targeted OpenSSL but is not limited to just that software. OpenSSL was targeted due to the researcher’s familiarity with the OpenSSL code.

What CPUs are affected by this vulnerability?
The researchers verified that this vulnerability is present on Intel Skylake CPUs (6th generation Core models e.g. i7 6700K). However any Intel CPU which implements HT is likely to have this vulnerability. Intel’s Nehalem architecture first introduced HT in 2008. The researchers believe AMD Ryzen CPUs may be affected but did not confirm this.

How can I protect myself from this vulnerability?
OpenSSL have added a fix to version 1.1.1 and older versions greater than version 1.1.0i (Source)

However the only true means of mitigating this vulnerability for all software is to disable Intel’s HT. The operating system distribution OpenBSD has done so since June this year. Similarly Intel within their new 9th generation Core CPUs disabled HT to enable hardware protections against the Meltdown, Spectre and L1 Terminal Fault vulnerabilities. They did so to their gaming focused CPUs since many games don’t leverage HT and thus don’t suffer a performance penalty from not using it. It doesn’t appear that HT was removed for security concerns since the Core i9 9900K still features it.

Since corporate organizations may have invested in software that uses HT; they should only consider turning it off if continuing to use it places them at a high risk of exploitation and would place them outside of what they consider an acceptable risk. They will then need to consider the performance/security trade-off of doing so.

If you use Intel HT I would recommend testing your own software with this feature turned off to tell if it has too much of a performance penalty for your particular use cases. From researching this it is not a straightforward answer of turning it off and definitely not experiencing any slowdown; it may or may not happen depending on how you use your system and the software you use.

I have provided links to definitions of HT above and some references below which may assist you in making a decision to disable or leave it enabled. That research also pointed out that if you wish to disable HT; please do so from the BIOS (defined) of your computing system since it will have a blanket disablement across all software and your operating system. A software disablement can work but disabling via the BIOS leaves less room for error. Please refer to your system manufacturer or motherboard user guide for the steps to enter the BIOS of the system and disable this feature.

As more details of this vulnerability emerge I will consider disabling this feature on my water cooled Intel Core i9 7980XE CPU. Windows detects it with 36 logical cores; with HT disabled it will “drop” to 18 physical cores. I’ll need to evaluate the performance impact (if any) for my particular use cases. Given the attacker will need to already have compromised my system and the attack is of high complexity; it’s less likely I will need to disable HT. My existing security controls are more than enough to mitigate this risk; but your system, configuration and risk appetite may be different.

Thank you.



Why You Disable Hyper-Threading or NOT, and How to Know the Difference


Nehalem – Everything You Need to Know about Intel’s New Architecture

Source: https://www.anandtech.com/show/2594/8


Performance-impact of Hyper-Threading:



Is Hyper-Threading a Fundamental Security Risk?


Why does disabling hyperthreading supposedly give better gaming performance? (This is again a gaming focused discussion but would be relevant for software that does not use HT):



Why on earth would you disable Hyperthreading? (This is a more gaming focused discussion but would be relevant for software that does not use HT. Please ignore the advert spam posts for software named CPUCores, it’s confirmedsnake oil”):



Vendors Respond to Foreshadow (L1TF) Vulnerabilities

Yesterday, academic and security researchers publically disclosed (defined) 3 new vulnerabilities affecting Intel CPUs (AMD and ARM are not affected).

What are these new vulnerabilities and what can they allow an attacker to do?
The first vulnerability known as Foreshadow or CVE-2018-3615 is used to extract data from an Intel SGX (Software Guard Extensions)(defined) secure enclave (area) by creating a shadow copy of the SGX protected data but that copy does not have the protection of SGX and can be read/accessed by the attacker. The attacker can also re-direct speculative execution into copying further private/sensitive into the shadow copied area while at the same time making it appear that area is genuine and thus has the same protection as the real SGX protected data.

The second vulnerability (part of a wider Foreshadow Next Generation (NG) group of two variants) known as CVE-2018-3620 allows the reading of data copied into the level 1 cache (defined) of a CPU (defined) when that data is in use by a computer operating system e.g. Red Hat Linux, Apple macOS or Microsoft Windows.

The third vulnerability is the second and final variant of the Foreshadow NG group known as CVE-2018-3646.  This affects virtualised environments. If a CPU thread (defined) being directed by an attacker is able to read the level 1 cache of a CPU that is also shared by another thread by a victim user (within another virtualised environment but using the same physical CPU) while that request will be blocked; if the information the attacker is looking to steal is in the level 1 cache they may still get a glimpse of this information.

How can I protect myself from these new vulnerabilities?
For the first and second vulnerabilities; the microcode (defined)/firmware (defined) updates made available earlier this year coupled with the newly released updates for operating systems linked to below will mitigate these two issues.


For the third vulnerability; affecting virtualised (defined) environments there are operating system updates and microcode/firmware updates available that will occasionally clear the contents of the level 1 cache meaning that when the attacker attempts to read it they will not receive any benefit from doing so. Partially removing the usefulness of the cache will have a performance impact from a few percent up to 15 percent in the worst case scenario.

However to completely mitigate this third vulnerability a capability known as Core Scheduling needs to be leveraged. This ensures that only trusted/non attacker controlled virtual machines have access to the same thread (this capability is already available in some virtual machine (hypervisor)(defined) environments).

However in some environments if it cannot be guaranteed that all virtual machines are trustworthy the disabling of Intel Hyper Threading (this means that only 1 thread will work per CPU core)(otherwise known as simultaneous multi-threading (SMT)(defined)) may be necessary and will more significantly impact performance than just the level 1 cache clearing.

In summary for this third vulnerability; depending upon the virtualised environment you are using and the trustworthiness of the virtual machines you are using will determine how many of the these extra security measure you will need to take.

To be clear I am NOT advocating that Intel Hyper Threading/SMT be disabled EN MASSE for security reasons. As per the advice in the linked to advisories (below)(specifically Intel and VMware) ; you MAY wish to disable Intel Hyper Threading/SMT to mitigate the third vulnerability (CVE-2018-3646) depending upon the environment your virtualised machines are operating.

This Ars Technica article explains it very well: “if two virtual machines share a physical core, then the virtual machine using one logical core can potentially spy on the virtual machine using the other logical core. One option here is to disable hyperthreading on virtual-machine hosts. The other alternative is to ensure that virtual machines are bound to physical cores such that they don’t share.”


Please find below links to vendor responses on these vulnerabilities as well as videos that can help in understanding these vulnerabilities:

Thank you.


Foreshadow Vulnerability Official Website:

Intel’s Blog Post:

Intel’s FAQ Page:

Intel’s Security Advisory:

Intel’s Software Developer Guidance:

Red Hat’s Security Advisory:

Linux Kernel Patch:

Oracle’s Security Advisory:

Amazon Web Services’ Security Advisory:

Google Cloud Security’s Blog Post:

Microsoft Windows Azure’s Guidance:

Microsoft’s Windows Security Advisory (high level details):

Microsoft’s Technical Analysis of the Foreshadow Vulnerabilities:

VMware Security Advisories:


Foreshadow Video (explains the first vulnerability very well):

Intel’s Video (explains all 3 vulnerabilities):

Demonstration of the Foreshadow attack:

Red Hat’s Video (explains all 3 vulnerabilities):

Red Hat’s In-depth video of the 3 vulnerabilities: